FTAAN, Session 2

The Cevita conditions are the conditions of Cevita energy. Cevita energy is the perturbative energy of substringular states. So, Cevita conditions are the conditions of the perturbative energies of substringular states. Substringular states are the states of Planck phenomena related phenomena, the states of superstrings, the states of counterstrings, the states of cohomologies, and the states of singularities that bind the prior named types of states. Perturbation of substringular states is often short lived. When a perturbative substringular state is brought out of perturbation, the substringular state is brought into a Wess- Zumino condition via Anti-Cevita energy. Just as Cevita energy brings substringular phenomena into perturbation, Anti-Cevita energy brings substringular phenomena out of perturbation. Wess- Zumino conditions are the conditions of substringular phenomena that are not in perturbation. Anti-Cevita energy always produces a framework of certain Wess-Zumino conditions. Often, There are a certain amount of Cevita conditions and a certain amount of Wess-Zumino conditions that apply to an orbifold eigenset at the same time. A mass that is of a neutrino or of an electron is Yau-Exact per orbifold even though the particle itself tends to be perturbative at times. So, the conformal invariance of neutrinos and electrons has Wess-Zumino conditions because conformal invariance involves non-perturbations, and masses tend to be non-perturbative when their inertia is constant. Yet, as the neutrinos and electrons scatter upon something, the Yau-Exact characteristic becomes partially hermitian and perturbative with refference to the particles themselves, and their heat and entropy are non-hermitian and perturbative. Any mass has Kaluza-Klein topology to an extent (at least one orbifold). All Kaluza-Klein topology involves entropy because of the abelian nature of their light-cone-guage as a supplemental Dirac Hamiltonian. All entropy involves heat. Heat is generally displaced via convection because of the Gaussian norm conditions via mini-string of orbifold eigenbases through Real Reimmanian Fock supplementation. Thus, masses inertialwise tend to have a way of being Yau-Exact except for the entropy, heat, and plain energy that happen to exist as these alter differentiation-wise.